Sea Ice Simulations Performed with Forcing Fields Specified from a General Circulation Model as a Step Toward Modeling the Climate System in Total.

As a first step in the development of a fully coupled atmospheric ice model including ice dynamics, an Interannual simulation of the Arctic ice cover with GCM simulated surface fluxes and winds is compared to a Control equilibrium simulation using observed atmospheric forcing. For the simulated forc...

Full description

Bibliographic Details
Main Author: Loewe,Peter
Other Authors: MAX-PLANCK-INST FUER METEOROLOGIE HAMBURG (GERMANY F R)
Format: Text
Language:English
Published: 1987
Subjects:
Snow
Ice and Permafrost
Meteorology
*CLIMATE
*SEA ICE
MEAN
THICKNESS
ARCTIC OCEAN
TEMPERATURE
CONTROL
EQUILIBRIUM(GENERAL)
COMPUTERIZED SIMULATION
DAILY OCCURRENCE
VARIATIONS
ARCTIC REGIONS
COVERINGS
ICE
CYCLES
ATMOSPHERE MODELS
COUPLING(INTERACTION)
DRIFT
DIURNAL VARIATIONS
AMPLITUDE
AREA COVERAGE
ATMOSPHERIC TEMPERATURE
AIR WATER INTERACTIONS
SPATIAL DISTRIBUTION
MASS
RADIATION
WIND
SIMULATION
SEASONAL VARIATIONS
CLOUD COVER
SURFACES
SUMMER
CIRCULATION
MATHEMATICAL MODELS
DYNAMICS
VARIABLES
LOW RESOLUTION
BUDGETS
OCEAN SURFACE
SURFACE TEMPERATURE
THERMODYNAMICS
WINTER
*Ice Cover
*Air Ice Interactions
GCM(General Circulation Model)
Atmospheric Circulation
Climat modeling
Forcing Functions
ASH57
PE61102A
Arctic
Arctic Ocean
Ice
permafrost
Sea ice
Online Access:http://www.dtic.mil/docs/citations/ADA182889
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA182889
Description
Summary:As a first step in the development of a fully coupled atmospheric ice model including ice dynamics, an Interannual simulation of the Arctic ice cover with GCM simulated surface fluxes and winds is compared to a Control equilibrium simulation using observed atmospheric forcing. For the simulated forcing results form a coarse resolution GCM with specified sea surface temperatures and ice extents, but simulated cloud cover, are used. For the observed data, climatological temperatures and winds (with daily fluctuations added) are employed. Results from a thermodynamic sea ice model subjected to the simulated forcing are also reported for comparison. Main fields as ice thickness, compactness, and drift was well as radiative and wind forcing are analyzed, both in terms of the seasonal cycle and in terms of interannual variability. An analysis of regional mass budget and longitudinal variability of key variables is presented in addition to results covering the full spatial domain. Amplitude and phase of simulated annual cycles of total ice mass and extent are in good agreement with those of the Control cycles; the annual mean thickness being about 2.5m and ice extent in summer being about 50% of the extent in winter. The simulated spatial distribution of ice is however considerably distorted. Large portions of the Arctic Ocean become ice free each summer while marginal seas stay ice covered. This is caused by a wind forcing that is generally simulated too stationary and too strong on account of the GCM's low resolution.

Similar Items